Cerebrum Diencephalon: Medulla oblongata Pituitary

Medulla oblongata

Cerebellum

Diencephalon:

Cerebrum

Brain stem:

ThalamusEpithalamusHypothalamusPineal gland

MidbrainPons

Spinal cord

Pituitary

Central Nervous System (CNS)

• CNS consists of the brain and spinal cord

• Cephalization– Evolutionary development of the rostral

(anterior) portion of the CNS– Increased number of neurons in the head– Highest level is reached in the human brain

Embryonic Development

• Neural plate forms from ectoderm • Neural plate invaginates to form a

neural groove and neural folds

Figure 12.1, step 1

The neural plate forms from surface ectoderm.1

Head

Tail

Surfaceectoderm

Neuralplate

Figure 12.1, step 2

The neural plate invaginates, forming the neuralgroove, flanked by neural folds.2

Neural folds

Neuralgroove

Embryonic Development

• Neural groove fuses dorsally to form the neural tube

• Neural tube gives rise to the brain and spinal cord

Figure 12.1, step 3

Neural fold cells migrate to form the neural crest,which will form much of the PNS and many otherstructures.

3

Neural crest

Figure 12.1, step 4

The neural groove becomes the neural tube, whichwill form CNS structures.4

Surfaceectoderm

Head

Tail

Neuraltube

Embryonic Development

• Anterior end of the neural tube gives rise to three primary brain vesicles– Prosencephalon—forebrain– Mesencephalon—midbrain– Rhombencephalon—hindbrain

(a)Neuraltube

(b) Primary brainvesicles

Anterior(rostral)

Posterior(caudal)

Rhombencephalon(hindbrain)

Mesencephalon(midbrain)

Prosencephalon(forebrain)

Figure 12.2a-b

Embryonic Development

• Primary vesicles give rise to five secondary brain vesicles– Telencephalon and diencephalon arise

from the forebrain– Mesencephalon remains undivided– Metencephalon and myelencephalon arise

from the hindbrain

Embryonic Development

• Telencephalon cerebrum (two hemispheres with cortex, white matter, and basal nuclei)

• Diencephalon thalamus, hypothalamus, epithalamus, and retina

Embryonic Development

• Mesencephalon brain stem (midbrain)

• Metencephalon brain stem (pons) and cerebellum

• Myelencephalon brain stem (medulla oblongata)

• Central canal of the neural tube enlarges to form fluid-filled ventricles

(d) Adult brainstructures

(c) Secondary brainvesicles

Spinal cord

CerebellumBrain stem: medullaoblongata

Brain stem: pons

Brain stem: midbrain

Diencephalon(thalamus, hypothalamus,epithalamus), retina

Cerebrum: cerebralhemispheres (cortex,white matter, basal nuclei)

Myelencephalon

Metencephalon

Mesencephalon

Diencephalon

Telencephalon

Central canal

Fourthventricle

Cerebralaqueduct

Third ventricle

Lateralventricles

(e) Adultneural canalregions

Figure 12.2c-e

Effect of Space Restriction on Brain Development

• Midbrain flexure and cervical flexure cause forebrain to move toward the brain stem

• Cerebral hemispheres grow posteriorly and laterally

• Cerebral hemisphere surfaces crease and fold into convolutions

Figure 12.3a

Metencephalon

Anterior (rostral) Posterior (caudal)

MesencephalonDiencephalon Midbrain

CervicalSpinal cord

FlexuresTelencephalonMyelencephalon

(a) Week 5

Figure 12.3b

MidbrainCerebellumPonsMedulla oblongata

Spinal cord

Cerebral hemisphere

Outline of diencephalon

(b) Week 13

Figure 12.3c

CerebellumPonsMedullaoblongata Spinal cord

Cerebralhemisphere

(c) Week 26

Coverings of the Brain-Meninges

skinskulldura mater

arachnoid layer

pia mater

cerebral cortex

Menenges:1.Covers and protects CNS2.Protects blood vessels and

encloses venus sinuses3.Contains CSF4.Forms partition within the skull

Ventricles of the Brain

• Connected to one another and to the central canal of the spinal cord

• Lined by ependymal cells

Ventricles of the Brain

• Contain cerebrospinal fluid– Two C-shaped lateral ventricles in the

cerebral hemispheres– Third ventricle in the diencephalon– Fourth ventricle in the hindbrain, dorsal to

the pons, develops from the lumen of the neural tube

Cerebruspinal Fluid

Brain

Ventricles

CSF

Spinal Cord

Anterior View Saggital View

Rt. Ventricle Lf. Ventricle

Figure 12.5

Anterior horn

Interventricularforamen

Inferiorhorn

Lateralaperture

(b) Left lateral view

Lateral ventricle

Septum pellucidum

Third ventricle

Cerebral aqueduct

(a) Anterior view

Fourth ventricleCentral canal

Inferior horn

Posteriorhorn

MedianapertureLateralaperture

CSF • 150 ml in adult• contains: glucose, proteins,lactic acid,

urea, cations, anions, WBC Functions:

1.Reduces wt. of brain by 97%2.Prevents head injury3.Supplies brain with nutrition4.Transports hormones along

ventricular channels

Figure 12.26a

Superiorsagittal sinus

Arachnoid villus

Subarachnoid spaceArachnoid materMeningeal dura materPeriosteal dura mater

Right lateral ventricle(deep to cut)Choroid plexusof fourth ventricle

Central canalof spinal cord

Choroidplexus Interventricularforamen

Third ventricle

Cerebral aqueductLateral apertureFourth ventricleMedian aperture

(a) CSF circulation

CSF is produced by thechoroid plexus of eachventricle.

1

CSF flows through theventricles and into the subarachnoid space via the median and lateral apertures. Some CSF flows through the central canal of the spinal cord.

2

CSF flows through thesubarachnoid space. 3

CSF is absorbed into the dural venoussinuses via the arachnoid villi. 4

1

2

3

4

Figure 12.26b

Ependymalcells

Capillary

Connectivetissue ofpia mater

Wastes andunnecessarysolutes absorbed

Sectionof choroidplexus

(b) CSF formation by choroid plexuses

Cavity ofventricle

CSF forms as a filtratecontaining glucose, oxygen, vitamins, and ions(Na+, Cl–, Mg2+, etc.)

Blood-Brain Barrier

1. Protects the brain from "foreign substances" in the blood that may injure the brain.

2. Protects the brain from hormones and neurotransmitters in the rest of the body.

3. Maintains a constant environmentfor the brain.

Blood-Brain Barrier

• Composition– Continuous endothelium of capillary walls– Basal lamina– Feet of astrocytes

• Provide signal to endothelium for the formation of tight junctions

Figure 11.3a

(a) Astrocytes are the most abundantCNS neuroglia.

Capillary

Neuron

Astrocyte

Blood-Brain Barrier: Functions

• Selective barrier– Allows nutrients to move by facilitated

diffusion– Allows any fat-soluble substances to pass,

including alcohol, nicotine, and anesthetics • Absent in some areas, hypothalamus,

pitutary, pineal body and vomiting center

The BBB can be broken down by

1. Hypertension (high blood pressure): high blood pressure opens the BBB.

2. Development: the BBB is not fully formed at birth.3. Hyperosmolitity: a high concentration of a substance in

the blood can open the BBB.4. Microwaves: exposure to microwaves can open the

BBB. 5. Radiation: exposure to radiation can open the BBB.6. Infection: exposure to infectious agents can open the

BBB.7. Trauma, Ischemia, Inflammation, Pressure: injury to

the brain can open the BBB.

Cerebral Hemispheres

• Surface markings– Ridges (gyri), shallow grooves (sulci), and

deep grooves (fissures)– Five lobes

• Frontal• Parietal • Temporal • Occipital• Insula

Cerebral Hemispheres

• Surface markings– Central sulcus

• Separates the precentral gyrus of the frontal lobe and the postcentral gyrus of the parietal lobe

– Longitudinal fissure• Separates the two hemispheres

– Transverse cerebral fissure• Separates the cerebrum and the

cerebellum

Figure 12.6a

Postcentralgyrus

Centralsulcus

Precentralgyrus

Frontallobe

(a)

Parietal lobeParieto-occipital sulcus(on medial surfaceof hemisphere)Lateral sulcus

Transverse cerebral fissure

Occipital lobeTemporal lobe

CerebellumPons

Medulla oblongataSpinal cord

Cortex (gray matter)

Fissure(a deepsulcus)

Gyrus

SulcusWhite matter

Figure 12.6b

Centralsulcus

(b)

Frontal lobe

Temporal lobe(pulled down)

Gyri of insula

Figure 12.6c

Parietallobe

Frontal lobe

Right cerebralhemisphereOccipitallobe

Left cerebralhemisphere

Cerebral veinsand arteriescovered byarachnoidmater

Longitudinalfissure

Posterior(c)

Anterior

Figure 12.6d

Left cerebralhemisphere

TransversecerebralfissureCerebellum

Brain stem

(d)

Cerebral Cortex

• Thin (2–4 mm) superficial layer of gray matter• 40% of the mass of the brain• Site of conscious mind: awareness, sensory

perception, voluntary motor initiation, communication, memory storage, understanding

• Each hemisphere connects to contralateral side of the body

• There is lateralization of cortical function in the hemispheres

Functional Areas of the Cerebral Cortex

• The three types of functional areas are:– Motor areas—control voluntary movement– Sensory areas—conscious awareness of

sensation– Association areas—integrate diverse

information• Conscious behavior involves the entire

cortex

Motor Areas

• Primary (somatic) motor cortex• Premotor cortex• Broca’s area• Frontal eye field

Figure 12.8a

Gustatory cortex(in insula)

Primary motor cortexPremotor cortexFrontal eye field

Working memoryfor spatial tasksExecutive area fortask managementWorking memory forobject-recall tasks

Broca’s area(outlined by dashes)

Solving complex,multitask problems

(a) Lateral view, left cerebral hemisphere

Motor areas

Prefrontal cortex

Sensory areas and relatedassociation areas

Central sulcus

Primary somatosensorycortexSomatosensoryassociation cortex

Somaticsensation

Taste

Wernicke’s area(outlined by dashes)

Primary visualcortexVisualassociation area

Vision

Auditoryassociation areaPrimaryauditory cortex

Hearing

Primary motor cortex Motor association cortex Primary sensory cortexSensory association cortex Multimodal association cortex

Primary Motor Cortex

• Large pyramidal cells of the precentral gyri• Long axons pyramidal (corticospinal) tracts • Allows conscious control of precise, skilled,

voluntary movements• Motor homunculi: upside-down caricatures

representing the motor innervation of body regions

Figure 12.9

Toes

Swallowing

Tongue

Jaw

Primary motorcortex(precentral gyrus)

MotorMotor map inprecentral gyrus

Posterior

Anterior

Premotor Cortex

• Anterior to the precentral gyrus• Controls learned, repetitious, or

patterned motor skills• Coordinates simultaneous or sequential

actions • Involved in the planning of movements

that depend on sensory feedback

Broca’s Area

• Anterior to the inferior region of the premotor area

• Present in one hemisphere (usually the left)

• A motor speech area that directs muscles of the tongue

• Is active as one prepares to speak

Frontal Eye Field

• Anterior to the premotor cortex and superior to Broca’s area

• Controls voluntary eye movements

Sensory Areas

• Primary somatosensory cortex

• Somatosensory association cortex

• Visual areas• Auditory areas

• Olfactory cortex• Gustatory cortex• Visceral sensory

area• Vestibular cortex

Figure 12.8a

Gustatory cortex(in insula)

Primary motor cortexPremotor cortexFrontal eye field

Working memoryfor spatial tasksExecutive area fortask managementWorking memory forobject-recall tasks

Broca’s area(outlined by dashes)

Solving complex,multitask problems

(a) Lateral view, left cerebral hemisphere

Motor areas

Prefrontal cortex

Sensory areas and relatedassociation areas

Central sulcus

Primary somatosensorycortexSomatosensoryassociation cortex

Somaticsensation

Taste

Wernicke’s area(outlined by dashes)

Primary visualcortexVisualassociation area

Vision

Auditoryassociation areaPrimaryauditory cortex

Hearing

Primary motor cortex Motor association cortex Primary sensory cortexSensory association cortex Multimodal association cortex

Motor, Sensory & Association Cortex

Motor, Sensory & Association Cortex

Primary Somatosensory Cortex

• In the postcentral gyri• Receives sensory information from the

skin, skeletal muscles, and joints• Capable of spatial discrimination:

identification of body region being stimulated

Figure 12.9

Genitals

Intra-abdominal

Primary somato-sensory cortex(postcentral gyrus)

SensorySensory map inpostcentral gyrus

Posterior

Anterior

Somatosensory Association Cortex

• Posterior to the primary somatosensory cortex

• Integrates sensory input from primary somatosensory cortex

• Determines size, texture, and relationship of parts of objects being felt

Visual Areas

• Primary visual (striate) cortex– Extreme posterior tip of the occipital lobe– Most of it is buried in the calcarine sulcus– Receives visual information from the

retinas

Visual Areas

• Visual association area– Surrounds the primary visual cortex– Uses past visual experiences to interpret

visual stimuli (e.g., color, form, and movement)

– Complex processing involves entire posterior half of the hemispheres

Auditory Areas

• Primary auditory cortex– Superior margin of the temporal lobes– Interprets information from inner ear as

pitch, loudness, and location• Auditory association area

– Located posterior to the primary auditory cortex

– Stores memories of sounds and permits perception of sounds

OIfactory Cortex

• Medial aspect of temporal lobes (in piriform lobes)

• Part of the primitive rhinencephalon, along with the olfactory bulbs and tracts– (Remainder of the rhinencephalon in

humans is part of the limbic system)• Region of conscious awareness of

odors

Gustatory Cortex

• In the insula• Involved in the perception of taste

Visceral Sensory Area

• Posterior to gustatory cortex• Conscious perception of visceral

sensations, e.g., upset stomach or full bladder

Vestibular Cortex

• Posterior part of the insula and adjacent parietal cortex

• Responsible for conscious awareness of balance (position of the head in space)

Figure 12.8b

Frontal eye field

Prefrontalcortex

Processes emotionsrelated to personaland social interactions

(b) Parasagittal view, right hemisphere

Olfactory bulbOrbitofrontalcortex

Olfactory tractFornix

Temporal lobe

Corpuscallosum

Premotor cortexPrimarymotor cortex

Cingulategyrus Central sulcus

Primary somatosensorycortex

Parietal lobe

Parieto-occipitalsulcus

Somatosensoryassociation cortex

OccipitallobeVisualassociationarea

Calcarine sulcusParahippocampalgyrus

UncusPrimaryolfactory cortex

Primaryvisual cortex

Primary motor cortex Motor association cortex Primary sensory cortexSensory association cortex Multimodal association cortex

Multimodal Association Areas

• Receive inputs from multiple sensory areas

• Send outputs to multiple areas, including the premotor cortex

• Allow us to give meaning to information received, store it as memory, compare it to previous experience, and decide on action to take

Multimodal Association Areas

• Three parts–Anterior association area

(prefrontal cortex)–Posterior association area–Limbic association area

Anterior Association Area (Prefrontal Cortex)

• Most complicated cortical region• Involved with intellect, cognition, recall,

and personality• Contains working memory needed for

judgment, reasoning, persistence, and conscience

• Development depends on feedback from social environment

Posterior Association Area

• Large region in temporal, parietal, and occipital lobes

• Plays a role in recognizing patterns and faces and localizing us in space

• Involved in understanding written and spoken language (Wernicke’s area)

Limbic Association Area

• Part of the limbic system• Provides emotional impact that helps

establish memories

The Limbic SystemThe Limbic SystemThe Limbic System

cerebrum corpus callosum

thalamus

cerebellum

medulla oblongata

hypothalamus

pituitarypons

spinal cord

Pineal glandmid brain

Cerebrum

• Involved with higher brain functions.

• Processes sensory information.• Initiates motor functions.• Integrates information.

Cerebrum Cross-SectionCerebrum Cross-Section

basal ganglia ventricles

corpus callosum

white matter

cerebral cortex

Right-Left Specialization of the Cerebrum

left side– language development– mathematical & learning capabilities– sequential thought processes

right side– visual spatial skills– musical and artistic activities– intuitive abilities

Electroencephalogram (EEG)

• Records electrical activity that accompanies brain function

• Measures electrical potential differences between various cortical areas

Figure 12.20a

(a) Scalp electrodes are used to record brain waveactivity (EEG).

Brain Waves

• Patterns of neuronal electrical activity • Generated by synaptic activity in the

cortex• Each person’s brain waves are unique• Can be grouped into four classes based

on frequency measured as Hertz (Hz)

Types of Brain WavesAlpha waves:• 8-13 Hz• awake or resting w/eyes closed• disappear during sleep

Beta Waves:• 14-30 Hz• sensory input and mental activity

Brain WavesTheta Waves:• 4-7 Hz• emotional stress

Delta Waves:• 1-5 Hz• deep sleep in adults• normal in awake infants

Figure 12.20b

Alpha waves—awake but relaxed

Beta waves—awake, alert

Theta waves—common in children

Delta waves—deep sleep

(b) Brain waves shown in EEGs fall intofour general classes.

1-second interval

Brain Waves: State of the Brain

• Change with age, sensory stimuli, brain disease, and the chemical state of the body

• EEGs used to diagnose and localize brain lesions, tumors, infarcts, infections, abscesses, and epileptic lesions

• A flat EEG (no electrical activity) is clinical evidence of death

Epilepsy

• A victim of epilepsy may lose consciousness, fall stiffly, and have uncontrollable jerking

• Epilepsy is not associated with intellectual impairments

• Epilepsy occurs in 1% of the population

Epileptic Seizures

• Absence seizures, or petit mal– Mild seizures seen in young children where

the expression goes blank• Tonic-clonic (grand mal) seizures

– Victim loses consciousness, bones are often broken due to intense contractions, may experience loss of bowel and bladder control, and severe biting of the tongue

Control of Epilepsy

• Anticonvulsive drugs• Vagus nerve stimulators implanted

under the skin of the chest can keep electrical activity of the brain from becoming chaotic

Diencephalon• Thalamus• Epithalamus:

- pineal- habenular nuclei

• Hypothalamus• Subthalamus

- subthalamic nuclei

Diencephalon

thalamus

hypothalamus

pituitary

Diencephalon

Thalamus

• Relay center for sensory tracts from the spinal cord to the cerebrum.

• Contains centers for sensation of pain, temperature, and touch.

• Involved with emotions and alerting or arousal mechanisms.

Thalamus

The Reticular Formation

Epithalamus

Pineal gland & habenular nuclei

Subthalamus• Subthalamic nuclei• Portions of red nucleus• Portions of substantia nigra (dopamine)

Substantia nigraSubthalamic nuclei

Red nucleus

Substantia nigra

Hypothalamus

• autonomic control center- blood pressure, rate and force of heart contraction, center for emotional response and behavior

• body temperature• water balance and thirst• sleep/wake cycles• appetite• sexual arousal• control of endocrine functioning:Acts on the pituitary gland through the

release of neurosecretions.

Regulates:

Hypothalamus

Pituitary

• Cerebellar peduncles• Tectum• Superior colliculi• Inferior colliculi• Substantia nigra• Red nuclei

Midbrain

thalamus

Red nucleusSubstantia nigra

Posterior

Anterior

Midbrain

• Contains ascending and descending tracts to the cerebrum and thalamus.

• Reflex center for eye muscles.• Also involved with processing visual

and auditory information (connects head movements with visual and auditory stimuli).

Pons

• Connects the two halves of the cerebellum.

• Regulates breathing.• Associated w/ cranial

nerves V, VI, VII, & VIII

Medulla Oblongata• Composed of nerve tracts

decusate• An extension of the spinal

cord• Almost all of the cranial

nerves arise from this region• (VIII, IX, X, XI, XII)

Medulla Oblongata

Medulla Oblongata

Contains control centers for many subconscious activities• Respiratory rate• Heart rate• Arteriole constriction• Swallowing• Hiccupping• Coughing• Sneezing

The Cerebellum

• 11% of brain mass• Dorsal to the pons and medulla• Controls fine movement

coordination • Balance and equilibrium • Muscle tone

Anatomy of the Cerebellum

• Two hemispheres connected by vermis• Each hemisphere has three lobes

– Anterior, posterior, and flocculonodular • Folia—transversely oriented gyri• Arbor vitae—distinctive treelike pattern

of the cerebellar white matter

Figure 12.17b

(b)

Medullaoblongata

Flocculonodularlobe

Choroidplexus offourth ventricle

Posteriorlobe

Arborvitae

Cerebellar cortexAnterior lobe

Cerebellarpeduncles• Superior• Middle• Inferior

Importance of Sleep

• Slow-wave sleep (NREM stages 3 and 4) is presumed to be the restorative stage

• People deprived of REM sleep become moody and depressed

• REM sleep may be a reverse learning process where superfluous information is purged from the brain

• Daily sleep requirements decline with age• Stage 4 sleep declines steadily and may

disappear after age 60

Stages of Sleep

Sleep Disorders

• Narcolepsy – Lapsing abruptly into sleep from the awake state

• Insomnia – Chronic inability to obtain the amount or quality of

sleep needed• Sleep apnea

– Temporary cessation of breathing during sleep

Learning & Memory

Sensory organs

Stimulus

Sensory Memory(millisecond-1)

( )

Short-Term MemoryWorking Memory

(< 1 minute)

Long-Term Memory( days, months, years)

perception

attention

forgettingrepetition

Learning & MemorySensory Memory:

A sensory memory exists for each sensory channel:

• iconic memory for visual stimuli

• echoic memory for aural stimuli

• haptic memory for touch

Information sensory memory short-term memory by attention, thereby filtering the stimuli to only those which are of interest at a given time.

Learning & MemoryShort-term Memory:

• acts as a scratch-pad for temporary recall of the information under process

• can contain at any one time seven, plus or minus two, "chunks" of information

• lasts around twenty seconds.

Short-term Memory Quiz (30 sec)

eggsdrawingrockapplefocusmissionfavorice

brainflagtrialpartnerhouselifechair

Learning & MemoryLong-term Memory:

• intended for storage of information over a long time.

• Short-termlong-term (rehearsal)

• Little decay

• Storage

• Deletion- decay and interference

• Retrieval-recall and recognition

Learning & MemoryLong-term Memory:

Why we forget:

• fading (trace decay) over time

• interference (overlaying new information over the old)

• lack of retrieval cues.

Learning & MemoryEncoding in Long-term Memory:

• Organizing

• Practicing

• Spacing

• Making meaning

• Emotionally engaging

The Spinal CordCervical spinal nerves

Thoracic spinal nerves

Lumbar spinal nerves

Sacral spinal nerves

Conus medullaris

Cauda equina

Lumbar TapCollect CSF for testing

The Spinal CordThe Spinal Cord

spinal cord

spinal nerve

vertebra

Nerve Pathways into the Spinal Cord

Nerve Pathways into the Spinal Cord sensory

pathway

motor pathway

Somatic Sensory Pathway

Ascending Spinal Cord Tract

Ascending Spinal Cord Tract

• 1st order neuron-cutaneous receptors of skin and proprioceptors spinal cord or brain stem

• 2nd order neuron- to thalamus or cerebellum

• 3rd order neuron- to somatosensory cortex of cerebrum

Conducts sensory impulses upward through 3 successive chains of neurons

Descending Spinal Cord Tract

Traumatic Brain Injuries• Concussion• Contusion• Subdural or subarachnoid

hemorrhage• Contrecoup injury• Punch Drunk Syndrome

Cerebrovascular Accidents (CVAs)

• Ischemia• Thrombus• Embolism• Arteriosclerosis• Stroke

Stroke

Degenerative brain diseases

• Schizophrenia• Parkinson’s• Alzheimer’s• Down’s • Huntington’s Chorea• MS• Epilepsy

Parkinson’s disease• Substantia nigra in midbrain• Dopamine

- affects brain processes controlling:• movement• balance• walking• emotional response• ability to experience pleasure

and pain.

Parkinson’s diseaseCauses:• Genetics• Environmental chemicals (e.g., PCBs)• Thyroid disorders• Repeated head injury

Symptoms of Parkinson's Disease:• resting tremor on one side of the body• generalized slowness of movement (bradykinesia) • stiffness of limbs (rigidity) • gait or balance problems (postural dysfunction).

Parkinson’s diseaseTreatments:

• L-dopa• Deprenyl• Deep brain stimulation w/electrodes• Fetal tissue

Parkinson’s disease

F-Dopa deficiency

Alzheimer’s Disease

Results in dementia• 5-15% over age 65• 50% over age 85

Associated with :• Acetylcholine shortage• Amyloid plaques• Neurofibullary tangles

PET Scans

Huntington’s Disease

Fatal hereditary disorder• Onset at ~40 years• Fatal w/in 15 years• Dance-like movement

Associated with :• Huntingtin protein

1. What layer of tissue adheres most tightly to the brain?

2. CSF stands for-------.

3. What does it do?

4. What does the thalamus do?

5. What does the vestibulocochlear nerve control?

6. Where is dark matter located in the spinal cord?

7. A thrombus that moves to a new site is called ----.

INQUIRY